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环境干旱驱动干旱河谷63种灌木根系生物量分配比例的纬度格局。

Environmental aridity driving latitudinal pattern of biomass allocation fractions in root systems of 63 shrub species in dry valleys.

作者信息

Yang Yu, Wang Zilong, Bao Weikai, Wu Ning, Hu Hui, Yang Tinghui, Li Xiaojuan, Nkrumah Deborah Traselin, Li Fanglan

机构信息

Chengdu Institute of Biology Chinese Academy of Sciences Chengdu China.

University of Chinese Academy of Sciences Beijing China.

出版信息

Ecol Evol. 2024 Aug 7;14(8):e70091. doi: 10.1002/ece3.70091. eCollection 2024 Aug.

DOI:10.1002/ece3.70091
PMID:39114169
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11303844/
Abstract

Fine roots and absorptive roots play key roles in acquiring resources throughout soil profiles and determining plant functions along environmental gradients. Yet, the geographical pattern of carbon allocation in fine roots, particularly in absorptive roots, and their relations with plant sizes and evironment are less understood. We sampled 243 xerophytic shrubs from 63 species distributed along the latitudinal gradient (23°N to 32°N) in dry valleys of southwest China and synthetically measured biomass fractions of plant organs, especially fine roots and absorptive roots (1st to 3rd root order). We identified latitudinal patterns of biomass allocation fractions of organs and their relationships with plant sizes and environmental factors. The latitudinal patterns of both absorptive root and fine-root fractions followed weak unimodal distributions; stem biomass fraction increased with the latitude, while the leaf biomass fraction decreased. The fraction of fine-root biomass had negative relationships with plant height and root depth. The fractions of root, fine root, and absorptive root biomass were largely explained by soil moisture. Furthermore, fraction of fine-root biomass increased in a relatively humid environment. Overall, soil moisture was the most important factor in driving latitudinal patterns of biomass fraction. Our study highlighted that functional redistribution of root system biomass was the critical adaptive strategy along a latitudinal gradient.

摘要

细根和吸收根在获取整个土壤剖面中的资源以及决定植物在环境梯度中的功能方面发挥着关键作用。然而,细根尤其是吸收根中碳分配的地理格局,以及它们与植物大小和环境的关系却鲜为人知。我们在中国西南干旱河谷沿纬度梯度(北纬23°至32°)分布的63个物种中采集了243株旱生灌木样本,并综合测量了植物器官的生物量比例,特别是细根和吸收根(第1至第3级根序)。我们确定了器官生物量分配比例的纬度格局及其与植物大小和环境因子的关系。吸收根和细根比例的纬度格局均呈弱单峰分布;茎生物量比例随纬度增加,而叶生物量比例下降。细根生物量比例与株高和根深呈负相关。根、细根和吸收根生物量比例在很大程度上受土壤湿度的影响。此外,在相对湿润的环境中细根生物量比例增加。总体而言,土壤湿度是驱动生物量比例纬度格局的最重要因素。我们的研究强调,根系生物量的功能重新分配是沿纬度梯度的关键适应策略。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/a6a7/11303844/69d50a2774cc/ECE3-14-e70091-g008.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/a6a7/11303844/8a8d181d3f38/ECE3-14-e70091-g001.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/a6a7/11303844/8a8d181d3f38/ECE3-14-e70091-g001.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/a6a7/11303844/69d50a2774cc/ECE3-14-e70091-g008.jpg

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Tree biomass allocation differs by mycorrhizal association.树木生物量分配因菌根共生关系而异。
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Plant sizes and shapes above and belowground and their interactions with climate.地上和地下植物的大小和形状及其与气候的相互作用。
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The global distribution and environmental drivers of aboveground versus belowground plant biomass.地上与地下植物生物量的全球分布及其环境驱动因素。
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